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Transcript
Application Note 140
October 2013
Basic Concepts of Linear Regulator and Switching
Mode Power Supplies
Henry J. Zhang
ABSTRACT
This article explains the basic concepts of linear regulators
and switching mode power supplies (SMPS). It is aimed
at system engineers who may not be very familiar with
power supply designs and selection. The basic operating
principles of linear regulators and SMPS are explained
and the advantages and disadvantages of each solution
are discussed. The buck step-down converter is used as
an example to further explain the design considerations
of a switching regulator.
INTRODUCTION
Today’s designs require an increasing number of power
rails and supply solutions in electronics systems, with
loads ranging from a few mA for standby supplies to over
100A for ASIC voltage regulators. It is important to choose
the appropriate solution for the targeted application and
to meet specified performance requirements, such as
high efficiency, tight printed circuit board (PCB) space,
accurate output regulation, fast transient response, low
solution cost, etc. Power management design is becoming
a more frequent and challenging task for system designers,
many of whom may not have strong power backgrounds.
A power converter generates output voltage and current
for the load from a given input power source. It needs to
meet the load voltage or current regulation requirement
during steady-state and transient conditions. It also must
protect the load and system in case of a component
failure. Depending on the specific application, a designer
can choose either a linear regulator (LR) or a switching
mode power supply (SMPS) solution. To make the best
choice of a solution, it is essential for designers to be
familiar with the merits, drawbacks and design concerns
of each approach.
This article focuses on nonisolated power supply applications and provides an introduction to their operation and
design basics.
LINEAR REGULATORS
How a Linear Regulator Works
Let’s start with a simple example. In an embedded system,
a 12V bus rail is available from the front-end power supply.
On the system board, a 3.3V voltage is needed to power an
operational amplifier (op amp). The simplest approach to
generate the 3.3V is to use a resistor divider from the 12V
bus, as shown in Figure 1. Does it work well? The answer
is usually no. The op amp’s VCC pin current may vary under
different operating conditions. If a fixed resistor divider
is used, the IC VCC voltage varies with load. Besides, the
12V bus input may not be well regulated. There may be
many other loads in the same system sharing the 12V rail.
Because of the bus impedance, the 12V bus voltage varies with the bus loading conditions. As a result, a resistor
12VDC BUS
R1
3.3V
VCC
LOAD
R2
+
VX
–
AN140 F01
Figure 1. Resistor Divider Generates 3.3VDC from 12V Bus Input
L, LT, LTC, LTM, Linear Technology, LTspice, µModule, PolyPhase and the Linear logo are
registered trademarks and LTpowerCAD is a trademark of Linear Technology Corporation. All
other trademarks are the property of their respective owners.
an140fa
AN140-1
Application Note 140
divider cannot provide a regulated 3.3V to the op amp to
ensure its proper operation. Therefore, a dedicated voltage regulation loop is needed. As shown in Figure 2, the
feedback loop needs to adjust the top resistor R1 value
to dynamically regulate the 3.3V on VCC.
Q1
3.3V
+
LOAD
–
CO
VO = 3.3V
+
VFB
RB
VCC
LOAD
RA
VCC
+
+
VCE
E
–
R1
C
B
CURRENT
AMPLIFIER
ERROR
AMPLIFIER
12VBUS
FEEDBACK
REGULATOR
VIN = 12VBUS
LINEAR REGULATOR
+
VX
–
VREF
+
AN140 F03
VX
–
Figure 3. A Linear Regulator Implements a Variable Resistor
to Regulate Output Voltage
AN140 F02
Figure 2. Feedback Loop Adjusts Series Resistor R1 Value
to Regulate 3.3V
This kind of variable resistor can be implemented with a
linear regulator, as shown in Figure 3. A linear regulator
operates a bipolar or field effect power transistor (FET)
in its linear mode. So the transistor works as a variable
resistor in series with the output load. To establish the
feedback loop, conceptually, an error amplifier senses
the DC output voltage via a sampling resistor network RA
and RB, then compares the feedback voltage VFB with a
reference voltage VREF. The error amplifier output voltage
drives the base of the series power transistor via a current
amplifier. When either the input VBUS voltage decreases
or the load current increases, the VCC output voltage goes
down. The feedback voltage VFB decreases as well. As a
result, the feedback error amplifier and current amplifier
generate more current into the base of the transistor
Q1. This reduces the voltage drop VCE and hence brings
back the VCC output voltage, so that VFB equals VREF. On
the other hand, if the VCC output voltage goes up, in a
similar way, the negative feedback circuit increases VCE
to ensure the accurate regulation of the 3.3V output. In
summary, any variation of VO is absorbed by the linear
regulator transistor’s VCE voltage. So the output voltage
VCC is always constant and well regulated.
Why Use Linear Regulators?
The linear regulator has been widely used by industry for
a very long time. It was the basis for the power supply
industry until switching mode power supplies became
prevalent after the 1960s. Even today, linear regulators
are still widely used in a wide range of applications.
In addition to their simplicity of use, linear regulators have
other performance advantages. Power management suppliers have developed many integrated linear regulators.
A typical integrated linear regulator needs only VIN, VOUT,
FB and optional GND pins. Figure 4 shows a typical 3-pin
linear regulator, the LT1083, which was developed more
than 20 years ago by Linear Technology. It only needs an
input capacitor, output capacitor and two feedback resistors
to set the output voltage. Almost any electrical engineer
can design a supply with these simple linear regulators.
an140fa
AN140-2
Application Note 140
VIN ≥ 6.5V
IN
+
LT1083
ADJ
10µF
5V AT 7.5A
OUT
121Ω
1%
+
10µF*
TANTALUM
365Ω
1%
*REQUIRED FOR STABILITY
AN140 F04
work with low headroom (VIN – VO) are called low dropout
regulators (LDOs).
It is also clear that a linear regulator or an LDO can only
provide step-down DC/DC conversion. In applications that
require VO voltage to be higher than VIN voltage, or need
negative VO voltage from a positive VIN voltage, linear
regulators obviously do not work.
Figure 4. Integrated Linear Regulator Example: 7.5A
Linear Regulator with Only Three Pins
100
One Drawback – A Linear Regulator Can Burn a Lot of
Power
A major drawback of using linear regulators can be the
excessive power dissipation of its series transistor Q1
operating in a linear mode. As explained previously, a linear regulator transistor is conceptually a variable resistor.
Since all the load current must pass through the series
transistor, its power dissipation is PLoss = (VIN – VO) •
IO. In this case, the efficiency of a linear regulator can be
quickly estimated by:
ηLR =
POUTPUT
VO •IO
V
=
= O
POUTPUT +PLOSS VO •IO +(VIN – VO)•IO VIN (1)
So in the Figure 1 example, when the input is 12V and
output is 3.3V, the linear regulator efficiency is just 27.5%.
In this case, 72.5% of the input power is just wasted and
generates heat in the regulator. This means that the transistor must have the thermal capability to handle its power/
heat dissipation at worst case at maximum VIN and full
load. So the size of the linear regulator and its heat sink
may be large, especially when VO is much less than VIN.
Figure 5 shows that the maximum efficiency of the linear
regulator is proportional to the VO/VIN ratio.
On the other hand, the linear regulator can be very efficient
if VO is close to VIN. However, the linear regulator (LR) has
another limitation, which is the minimum voltage difference between VIN and VO. The transistor in the LR must
be operated in its linear mode. So it requires a certain
minimum voltage drop across the collector to emitter
of a bipolar transistor or drain to source of a FET. When
VO is too close to VIN, the LR may be unable to regulate
output voltage anymore. The linear regulators that can
EFFICIENCY %
80
60
40
20
0
0
0.2
0.4
0.6
VO/VIN
0.8
1
AN140 F05
Figure 5. Maximum Linear Regulator Efficiency
vs, VO/VIN Ratio
Linear Regulator with Current Sharing for High Power [8]
For applications that require more power, the regulator must
be mounted separately on a heat sink to dissipate the heat.
In all-surface-mount systems, this is not an option, so the
limitation of power dissipation (1W for example) limits
the output current. Unfortunately, it is not easy to directly
parallel linear regulators to spread the generated heat.
LT3080
IN
VIN
1.2V TO 36V
VCONTROL
+
–
1µF
OUT
SET
RSET
VOUT = RSET • 10µA
VOUT
2.2µF
AN140 F06
Figure 6. Single Resistor Setting LDO LT3080 with a
Precision Current Source Reference
an140fa
AN140-3
Application Note 140
Replacing the voltage reference shown in Figure 3 with
a precision current source, allows the linear regulator to
be directly paralleled to spread the current load and thus
spread dissipated heat among the ICs. This makes it possible to use linear regulators in high output current, allsurface-mount applications, where only a limited amount
of heat can be dissipated in any single spot on a board.
The LT3080 is the first adjustable linear regulator that can
be used in parallel for higher current. As shown in Figure 6,
it has a precision zero TC 10µA internal current source
connected to the noninverting input of the operational
amplifier. With an external single voltage setting resistor
RSET, the linear regulator output voltage can be adjusted
from 0V to (VIN – VDROPOUT).
Figure 7 shows how easy it is to parallel LT3080s for
current sharing. Simply tie the SET pins of the LT3080s
together, the two regulators share the same reference
voltage. Because the operational amplifiers are precisely
trimmed, the offset voltage between the adjustment pin
and the output is less than 2mV. In this case, only 10mΩ
ballast resistance, which can be the sum of a small external
resistor and PCB trace resistance, is needed to balance
the load current with better than 80% equalized sharing.
Need even more power? Even paralleling 5 to 10 devices
is reasonable.
VIN
LT3080
VCONTROL
+
–
OUT 10mΩ
SET
VIN
4.5V TO 30V
VIN
LT3080
VCONTROL
+
–
1µF
OUT 10mΩ
SET
VOUT
3.3V
2A
100µF
165k
AN140 F07
Figure 7. Paralleling of Two LT3080 Linear Regulators for
Higher Output Current
Applications Where Linear Regulators Are Preferable
There are many applications in which linear regulators or
LDOs provide superior solutions to switching supplies,
including:
1. Simple/low cost solutions. Linear regulator or LDO
solutions are simple and easy to use, especially for
low power applications with low output current where
thermal stress is not critical. No external power inductor
is required.
2. Low noise/low ripple applications. For noise-sensitive
applications, such as communication and radio devices,
minimizing the supply noise is very critical. Linear
regulators have very low output voltage ripple because
there are no elements switching on and off frequently
and linear regulators can have very high bandwidth. So
there is little EMI problem. Some special LDOs, such
as Linear Technology’s LT1761 LDO family, have as low
as 20μVRMS noise voltage on the output. It is almost
impossible for an SMPS to achieve this low noise level.
An SMPS usually has mV of output ripple even with
very low ESR capacitors.
3. Fast transient applications. The linear regulator feedback loop is usually internal, so no external compensation is required. Typically, linear regulators have wider
control loop bandwidth and faster transient response
than that of SMPS.
4. Low dropout applications. For applications where
output voltage is close to the input voltage, LDOs may
be more efficient than an SMPS. There are very low
dropout LDOs (VLDO) such as Linear’s LTC1844, LT3020
and LTC3025 with from 20mV to 90mV dropout voltage
and up to 150mA current. The minimum input voltage
can be as low as 0.9V. Because there is no AC switching loss in an LR, the light load efficiency of an LR or
an LDO is similar to its full load efficiency. An SMPS
usually has lower light load efficiency because of its
AC switching losses. In battery powered applications
in which light load efficiency is also critical, an LDO
can provide a better solution than an SMPS.
In summary, designers use linear regulators or LDOs
because they are simple, low noise, low cost, easy to use
and provide fast transient response. If VO is close to VIN,
an LDO may be more efficient than an SMPS.
an140fa
AN140-4
Application Note 140
SWITCHING MODE POWER SUPPLY BASICS
The Most Popular Switching Supply—the Buck
Converter
Why Use a Switching Mode Supply?
Figure 8 shows the simplest and most popular switching
regulator, the buck DC/DC converter. It has two operating
modes, depending on if the transistor Q1 is turned on or
off. To simplify the discussion, all the power devices are
assumed to be ideal. When switch (transistor) Q1 is turned
on, the switching node voltage VSW = VIN and inductor
L current is being charged up by (VIN – VO). Figure 8(a)
shows the equivalent circuit in this inductor charging
mode. When switch Q1 is turned off, inductor current goes
through the freewheeling diode D1, as shown in Figure
8(b). The switching node voltage VSW = 0V and inductor
L current is discharged by the VO load. Since the ideal
inductor cannot have DC voltage in the steady state, the
average output voltage VO can be given as:
A quick answer is high efficiency. In an SMPS, the transistors are operated in switching mode instead of linear
mode. This means that when the transistor is on and
conducting current, the voltage drop across its power path
is minimal. When the transistor is off and blocking high
voltage, there is almost no current through its power path.
So the semiconductor transistor is like an ideal switch. The
power loss in the transistor is therefore minimized. High
efficiency, low power dissipation and high power density
(small size) are the main reasons for designers to use
SMPS instead of linear regulators or LDOs, especially in
high current applications. For example, nowadays a 12VIN,
3.3VOUT switching mode synchronous buck step-down
supply can usually achieve >90% efficiency vs less than
27.5% from a linear regulator. This means a power loss
or size reduction of at least eight times.
Q1
+
SW
+
+
–
IC(IN)
VO
L
IL
–
+V
GS1
+
D1
ICO
CO
LOAD
VIN
D • TS
TS
+
VL–
SW
+
VGS1
VSW
VIN
DUTY
CYCLE
Q1
+
–
VL–
T
VO(DC) = AVG[VSW]= ON • VIN
TS
(2)
IL
IC(IN)
VO
L
+
IL
VIN – VO
VL
VO
ICO
CO
LOAD
VIN
IL
A. INDUCTOR CHARGING MODE
+V –
L
SW
+
+
–
IL
D1
L
IC(IN)
VO
+
IL
VIN
ICO
CO
ICO
LOAD
VO
AN140 F08
B. INDUCTOR DISCHARGING MODE
Figure 8. Buck Converter Operating Modes and Typical Waveforms
an140fa
AN140-5
Application Note 140
where TON is the on-time interval within the switching
period TS. If the ratio of TON/TS is defined as duty cycle
D, the output voltage VO is:
T
VO(DC) = ON • VIN =D• VIN
TS
(3)
When the filter inductor L and output capacitor CO values
are sufficiently high, the output voltage VO is a DC voltage
with only mV ripple. In this case, for a 12V input buck
supply, conceptually, a 27.5% duty cycle provides a 3.3V
output voltage.
Other than the above averaging approach, there is another
way to derive the duty cycle equation. The ideal inductor
cannot have DC voltage in steady state. So it must maintain
inductor volt-second balance within a switching period.
According to the inductor voltage waveform in Figure 8,
volt-second balance requires:
(VIN – VO) • D • TS = VO • (1 – D) • TS(4)
Hence, VO = VIN • D
(5)
Equation (5) is the same as equation (3). The same voltsecond balance approach can be used for other DC/DC
topologies to derive the duty cycle vs VIN and VO equations.
Power Losses in a Buck Converter
DC Conduction Losses
With ideal components (zero voltage drop in the ON
state and zero switching loss), an ideal buck converter
is 100% efficient. In reality, power dissipation is always
associated with every power component. There are two
types of losses in an SMPS: DC conduction losses and
AC switching losses.
The conduction losses of a buck converter primarily result
from voltage drops across transistor Q1, diode D1 and
inductor L when they conduct current. To simplify the
discussion, the AC ripple of inductor current is neglected
in the following conduction loss calculation. If a MOSFET
is used as the power transistor, the conduction loss of
the MOSFET equals IO2 • RDS(ON) • D, where RDS(ON) is
the on-resistance of MOSFET Q1. The conduction power
loss of the diode equals IO • VD • (1 – D), where VD is the
forward voltage drop of the diode D1. The conduction
loss of the inductor equals IO2 • RDCR, where RDCR is the
copper resistance of the inductor winding. Therefore, the
conduction loss of the buck converter is approximately:
PCON_LOSS = IO2 • RDS(ON) • D + IO • VD • (1 – D) + IO2
• RDCR(6)
For example, a 12V input, 3.3V/10AMAX output buck supply
can use following components: MOSFET RDS(ON) = 10mΩ,
inductor RDCR = 2 mΩ, diode forward voltage VD = 0.5V.
Therefore, the conduction loss at full load is:
PCON_LOS = 102 • 10 • 10–3 • 0.275 + 10 • 0.5 •
(1 – 0.275) + 102 • 2 • 10–3(W) = 0.275W + 3.62W
+ 0.2W = 4.095W
(7)
Considering only conduction loss, the converter
efficiency is:
POUTPUT
ηBUCK_CON =
POUTPUT +PCON_LOSS
3.3V •10A
=
= 88.96%
33W + 4.095W
(8)
The above analysis shows that the freewheeling diode
consumes 3.62W power loss, which is much higher than
the conduction losses of the MOSFET Q1 and the inductor
L. To further improve efficiency, diode D1 can be replaced
with a MOSFET Q2, as shown in Figure 9. This converter
is referred to as a synchronous buck converter. Q2’s gate
requires signals complementary to the Q1 gate, i.e., Q2
Q1
SW
IC(IN)
+
–
VIN
L
VO
IL
ICO
Q2
CO
VGSQ1
LOAD
VGSQ2
DUTY
CYCLE
AN140 F09
Figure 9. Synchronous Buck Converter and Its Transistor Gate Signals
an140fa
AN140-6
Application Note 140
is only on when Q1 is off. The conduction loss of the
synchronous buck converter is:
PCON_LOSS = IO2 • RDS1(ON) • D + IO2 • RDS2(ON) • (1– D)
+ IO2 RDCR(9)
If a 10mΩ RDS(ON) MOSFET is used for Q2 as well, the
conduction loss and efficiency of the synchronous buck
converter are:
PCON_LOS = 102 • 0.01 • 0.275 + 102 • 0.01 •
(1 – 0.275) + 102 • 2 • 10–3(W) = 0.275W + 0.725W +
0.2W = 1.2W
(10)
ηBUCK_CON =
=
POUTPUT
POUTPUT +PCON_LOSS
3.3V •10A
= 96.45%
33W +1.2W
(11)
The above example shows that the synchronous buck is
more efficient than a conventional buck converter, especially
for low output voltage applications where the duty cycle
is small and the conduction time of the diode D1 is long.
AC Switching Losses
In addition to the DC conduction losses, there are other
AC/switching related power losses due to the nonideal
power components:
1.MOSFET switching losses. A real transistor requires
time to be turned on or off. So there are voltage and
current overlaps during the turn-on and turn-off transients, which generate AC switching losses. Figure 10
shows the typical switching waveforms of the MOSFET
∆TON
Q1
VGS
QGD
∆TOFF
QGD
t
VDS
IDS
EON
Q1 in the synchronous buck converter. The charging and
discharging of the top FET Q1’s parasitic capacitor CGD
with charge QGD determine most of the Q1 switching
time and related losses. In the synchronous buck, the
bottom FET Q2 switching loss is small, because Q2 is
always turned on after its body diode conducts and is
turned off before its body diode conducts, while the
voltage drop across the body diode is low. However,
the body diode reverse recovery charge of Q2 can
also increase the switching loss of the top FET Q1 and
can generate switching voltage ringing and EMI noise.
Equation (12) shows that the control FET Q1 switching
loss is proportional to the converter switching frequency
fS. The accurate calculation of the energy losses EON
and EOFF for Q1 is not simple but can be found from
MOSFET vendors’ application notes.
PSW_Q1 = (EON + EOFF) • fS(12)
2.Inductor core loss PSW_CORE. A real inductor also
has AC loss that is a function of switching frequency.
Inductor AC loss is primarily from the magnetic core
loss. In a high frequency SMPS, the core material may
be powdered iron or ferrite. In general, powdered iron
cores saturate softly but have high core loss, while ferrite material saturates more sharply but has less core
loss. Ferrites are ceramic ferromagnetic materials that
have a crystalline structure consisting of mixtures of
iron oxide with either manganese or zinc oxide. Core
losses are due mainly to magnetic hysteresis loss. The
core or inductor manufacturer usually provide the core
loss data for power supply designers to estimate the
AC inductor loss.
3.Other AC related losses. Other AC related losses
include the gate driver loss PSW_GATE, which equals
VDRV • QG • fS, and the dead time (when both top FET
Q1 and bottom FET Q2 are off) body diode conduction
loss, which is equal to (ΔTON + ΔTOFF) • VD(Q2) • fS.
In summary, the switching-related loss includes:
EOFF
t
AN140 F10
Figure 10. Typical Switching Waveform and Losses in the Top
FET Q1 in the Buck Converter
PSW_LOSS = PQ1_SW + PCORE_SW + PDRV + PDEADTIME (13)
The calculation of switching related losses is usually
not easy. The switching related losses are proportional
to switching frequency fS. In the 12VIN, 3.3VO/10AMAX
synchronous buck converter, the AC loss causes about
2% to 5% efficiency loss with 200kHz – 500kHz switchan140fa
AN140-7
Application Note 140
ing frequency. So the overall efficiency is about 93% at
full load, much better than that of an LR or LDO supply.
The heat or size reduction can be close to 10x.
Design Considerations of the Switching
Power Components
Switching Frequency Optimization
In general, higher switching frequency means smaller
size output filter components L and CO. As a result, the
size and cost of the power supply can be reduced. Higher
bandwidth can also improve load transient response.
However, higher switching frequency also means higher
AC-related power loss, which requires larger board space
or a heat sink to limit the thermal stress. Currently, for
≥10A output current applications, most step-down supplies operate in the range of 100kHz to 1MHz ~ 2MHz. For
< 10A load current, the switching frequency can be up to
several MHz. The optimum frequency for each design is
a result of careful trade-offs in size, cost, efficiency and
other performance parameters.
Output Inductor Selection
In a synchronous buck converter, the inductor peak-topeak ripple current can be calculated as:
ΔIL(P-P) =
(VIN – VO)• VO / VIN
L • fS
(14)
With a given switching frequency, a low inductance gives
large ripple current and results in large output ripple voltage. Large ripple current also increases MOSFET RMS
current and conduction losses. On the other hand, high
inductance means large inductor size and possible high
inductor DCR and conduction losses. In general, 10%
~ 60% peak-to-peak ripple current is chosen over the
maximum DC current ratio when selecting an inductor. The
inductor vendors usually specify the DCR, RMS (heating)
current and saturation current ratings. It is important to
design the maximum DC current and peak current of the
inductor within the vendor’s maximum ratings.
Power MOSFET Selection
When selecting a MOSFET for a buck converter, first make
sure its maximum VDS rating is higher than the supply
VIN(MAX) with sufficient margin. However, do not select a
FET with an excessively high voltage rating. For example,
for a 16VIN(MAX) supply, a 25V or 30V rated FET is a good
fit. A 60V rated FET can be excessive, because the FET
on-resistance usually increases with rated voltage. Next,
the FET’s on-resistance RDS(ON) and gate charge QG (or
QGD) are two most critical parameters. There is usually a
trade-off between the gate charge QG and on-resistance
RDS(ON). In general, a FET with small silicon die size has
low QG but high on-resistance RDS(ON), while a FET with
a large silicon die has low RDS(ON) but large QG. In a buck
converter, the top MOSFET Q1 takes both conduction loss
and AC switching loss. A low QG FET is usually needed for
Q1, especially in applications with low output voltage and
small duty cycle. The lower side synchronous FET Q2 has
small AC loss because it is usually turned on or off when
its VDS voltage is near zero. In this case, low RDS(ON) is
more important than QG for synchronous FET Q2. When a
single FET cannot handle the total power, several MOSFETs
can be used in parallel.
Input and Output Capacitor Selection
First, the capacitors should be selected with sufficient
voltage derating.
The input capacitor of a buck converter has pulsating
switching current with large ripple. Therefore, the input
capacitor should be selected with sufficient RMS ripple
current rating to ensure its lifetime. Aluminum electrolytic
capacitors and low ESR ceramic capacitors are usually
used in parallel at the input.
The output capacitor determines not only the output voltage ripple, but also the load transient performance. The
output voltage ripple can be calculated by Equation (15).
For high performance applications, both the ESR and total
capacitance are important to minimize output ripple voltage and to optimize load transient response. Usually, low
ESR tantalum, low ESR polymer capacitors and multilayer
ceramic capacitors (MLCC) are good choices.
1

∆VOUT ≈ ∆IL(P-P)• ESR+
8 • fS •COUT 

(15)
Close the Feedback Regulation Loop
There is another important design stage for a switching
mode supply—closing the regulation loop with a negative
feedback control scheme. This is usually a much more
challenging task than using an LR or LDO. It requires good
an140fa
AN140-8
Application Note 140
understanding of loop behavior and compensation design
to optimize dynamic performance with a stable loop.
Where, SZ_ESR = 2πfZ_ESR =
1
,
ESR •CO
Small Signal Model of the Buck Converter
As explained above, a switching converter changes its
operation mode as a function of the switch ON or OFF
state. It is a discrete and nonlinear system. To analyze the
feedback loop with the linear control method, linear small
signal modeling is needed [1]. Because of the output L-C
filter, the linear small signal transfer function of duty cycle
D to output VO is actually a second-order system with two
poles and one zero, as shown in Equation (16). There are
double poles located at the resonant frequency of the output
inductor and capacitor. There is a zero determined by the
output capacitance and the capacitor ESR.
(16)
(17)
Voltage Mode Control vs Current Mode Control
The output voltage can be regulated by a closed loop
system shown in Figure 11. For example, when the output
voltage increases, the feedback voltage VFB increases
and the output of the negative feedback error amplifier
decreases. So the duty cycle decreases. As a result, the
output voltage is pulled back to make VFB = VREF. The
compensation network of the error op amp can be a type I,
type II or type III feedback amplifier network [4]. There is
only one control loop to regulate the output. This scheme
is referred to as voltage mode control. Linear Technology’s
LTC3775 and LTC3861 are typical voltage mode buck
controllers.
L
RAMP
+
ESR
VIN
CO
VO
R
LOAD
VC
R2
–
D•T S
VFB
RAMP
+
COMPARATOR
COMP
VC
TS
D = k • VC
R1
+
D
–
+
–
D
PWM
–
VIN • 1+ S 
VO
 SZ_ESR 
GDV (s)= =
D 1+ S + S2
ωO •Q ωO2
DCR
1+
1
R ≈ 1
ωO = 2πfWO =
•
L •CO
L •CO
1+ ESR
R
VREF
AN140 F11
FEEDBACK CONTROL
Figure 11. Block Diagram of a Voltage Mode-Controlled Buck Converter
an140fa
AN140-9
Application Note 140
Figure 12 shows a 5V to 26V input, 1.2V/15A output synchronous buck supply using the LTC3775 voltage mode
buck controller. Due to the LTC3775’s leading-edge PWM
modulation architecture and very low (30ns) minimum
on-time, the supply operates well for applications that
converts a high voltage automotive or industrial power
supply down to the 1.2V low voltage required by today’s
microprocessors and programmable logic chips. [9] High
power applications require multiphase buck converters
with current sharing. With voltage mode control, an
additional current sharing loop is required to balance
current among parallel buck channels. A typical current
sharing method for voltage mode control is the masterslave method. The LTC3861 is such a PolyPhase® voltage
mode controller. Its very low, ±1.25mV, current sense offset
makes current sharing between paralleled phases very
accurate to balance the thermal stress. [10]
Current mode control uses two feedback loops: an
outer voltage loop similar to the control loop of voltage
mode-controlled converters, and an inner current loop
that feeds back the current signal into the control loop.
Figure 13 shows the conceptual block diagram of a peak
current mode control buck converter that directly senses
the output inductor current. With current mode control,
the inductor current is determined by the error op amp
output voltage. The inductor becomes a current source.
Therefore, the transfer function from op amp output, VC,
to supply output voltage VO becomes a single pole system.
This makes loop compensation much easier. The control
loop compensation has less dependency on the output
capacitor ESR zero, so it is possible to use all ceramic
output capacitors.
CF
220pF
DB
RILIMT
732Ω
VIN
ILIMT
RILIMB
57.6k
CVCC
4.7µF
TG
SENSE
ILIMB
INTVCC
CSS
0.01µF
C2
330pF
VIN
5V TO 26V
CIN1
330µF
35V
QT
CB
0.1µF
L1
0.36µH
SS
SW
FREQ
BG
FB
+
BOOST
LTC3775
RSET
39.2k
RA
10k
RSENSE
0.003Ω
+
QB
PGND
COUT
470µF
2.5V
×2
VOUT
1.2V
15A
MODE/SYNC
COMP RUN/SHDN
SGND
RB
10k
R2
C1 4.7k
3.9nF
AN140 F12
COUT : SANYO 2R5TPD470M5
DB: CMDSH4E
L1: IHLP-4040DZ-ER-R36-M11
QB: RJK0301DPB-00-J0
QT: RJK0305DPB-00-J0
Figure 12. The LTC3775 Voltage Mode Synchronous Buck Supply Offers
a High Step-Down Ratio
an140fa
AN140-10
Application Note 140
There are many other benefits from current mode control.
As shown in Figure 13, since the peak inductor current is
limited by the op amp VC in a cycle-by-cycle fashion, the
current mode-controlled system provides a more accurate
and faster current limit under overload conditions. The
in-rush inductor current is well controlled during start-up,
too. Also, the inductor current does not change quickly
when the input voltage changes, so the supply has good
line transient performance. When multiple converters are
paralleled, with current mode control, it is also very easy
to share current among supplies, which is important for
reliable high current applications using PolyPhase buck
converters. In general, a current mode-controlled converter
is more reliable than a voltage mode-controlled converter.
The current mode control scheme solution needs to sense
the current precisely. The current sensing signal is usually a small signal at a level of tens of millivolts that is
sensitive to switching noise. Therefore, proper and careful
PCB layout is needed. The current loop can be closed by
sensing the inductor current through a sensing resistor,
the inductor DCR voltage drop, or the MOSFET conduction
voltage drop. Typical current mode controllers include
Linear Technology’s LTC3851A and LTC3855.
L
Constant Frequency vs Constant On-Time Control
Typical voltage mode and current mode schemes in the
Voltage Mode Control vs Current Mode Control section
have constant switching frequency generated by controller
internal clocks. These constant switching frequency controllers can be easily synchronized, an important feature
for high current, PolyPhase buck controllers. However, if
the load step-up transient occurs just after the control FET
Q1 gate is turned off, the converter must wait the entire Q1
off-time until the next cycle to respond to the transient. In
applications with small duty cycles, the worst case delay
is close to one switching cycle.
In such low duty cycle applications, constant on-time valley current mode control has shorter latency to respond
to load step-up transients. In steady state operation, the
switching frequency of constant on-time buck converters
is nearly fixed. In the event of a transient, the switching
frequency can vary quickly to speed up the transient
response. As a result, the supply has improved transient
performance and output capacitance and its related cost
can be reduced.
However, with constant on-time control, the switching frequency may vary with line or load. The LTC3833 is a valley
RSEN
+
KI
ESR
VIN
ERROR OP AMP
OUTPUT
VO
R
LOAD
C
~IOUT
–
R2
INDUCTOR
CURRENT
SIGNAL
IL SIGNAL
+
–
–
COMPARATOR
CURRENT MODE CONTROL
VFB
COMPENSATION
NETWORK
SLOPE
COMP
VC
TOP FET
GATE SIGNAL
R1
+
D
–
+
–
D
PWM
SLOPE COMP
ERROR
0P AMP
VREF
AN140 F13
Figure 13. Block Diagram of a Current Mode-Controlled Buck Converter
an140fa
AN140-11
Application Note 140
current mode buck controller with a more sophisticated
controlled-on-time architecture—a variant of the constant
on-time control architecture with the distinction that the
on-time is controlled so that the switching frequency
remains constant over steady stage conditions under line
and load. With this architecture, the LTC3833 controller
has 20ns minimum on-time and allows step-down applications from up to 38VIN to 0.6VO. The controller can be
synchronized to an external clock in the 200kHz to 2MHz
frequency range. Figure 14 shows a typical LTC3833 supply
with 4.5V to 14V input and 1.5V/20A output. [11] Figure 15
shows that the supply can respond quickly to sudden,
high slew rate load transients. During the load step-up
transient, the switching frequency increases to provide
faster transient response. During the load step-down
transient, the duty-cycle drops to zero. Therefore only the
output inductor limits the current slew rate. In addition to
the LTC3833, for multiple outputs or PolyPhase applica-
INTVCC
VIN
RPGD
100k
CIN2
22µF
×2
LTC3833
+
VIN
4.5V TO 14V
CIN1
180µF
16V
VOUT
PGOOD
SENSE–
SENSE+
RUN
VRNG
TG
MODE/PLLIN
SW
EXTVCC
L1
0.47µH
DB
CITH2 47pF
RITH 84.5k
RT 137k
TRACK/SS
RSENSE
1.5mΩ
BOOST
CSS 0.1µF
CITH1 220pF
MT
INTVCC
RFB2
15k
CB
0.1µF
INTVCC
RFB1
10k
CVCC
4.7µF
COUT2
100µF
×2
+
COUT1
330µF
2.5V
×2
MB
BG
ITH
VOUT
1.5V
20A
PGND
RT
SGND
VOSNS+
VOSNS–
CIN1: SANYO 16SVP180M
COUT1: SANYO 2R5TPE330M9
DB: CENTRAL CMDSH-3
AN140 F14
L1: PULSE PA0515.471NLT
MB: RENESAS RJK0330DPB
MT: RENESAS RJK0305DPB
Figure 14. Fast, Controlled-On-Time Current Mode Supply Using the LTC3833
ILOAD
20A/DIV
ILOAD
20A/DIV
VOUT
50mV/DIV
ILOAD
20A/DIV
VOUT
50mV/DIV
VOUT
50mV/DIV
IL
20A/DIV
IL
20A/DIV
50µs/DIV
VIN = 12V
VOUT = 1.5V
LOAD TRANSIENT = 0A TO 20A
AN140 F15a
IL
20A/DIV
5µs/DIV
VIN = 12V
VOUT = 1.5V
LOAD STEP = 0A TO 20A
AN140 F15b
5µs/DIV
VIN = 12V
VOUT = 1.5V
LOAD RELEASE = 20A TO 0A
AN140 F15c
Figure 15. LTC3833 Supply Offers Fast Response During Rapid Load Step Transients
an140fa
AN140-12
Application Note 140
tions, the LTC3838 and LTC3839 controllers provide fast
transient, multiphase solutions.
Loop Bandwidth and Stability
A well designed SMPS is quiet, both electrically and acoustically. This is not the case with an undercompensated
system, which tends to be unstable. Typical symptoms of
an undercompensated power supply include: audible noise
from the magnetic components or ceramic capacitors, jitter
in the switching waveforms, oscillation of output voltage,
and so on. An overcompensated system can be very stable
and quiet, but at the cost of a slow transient response.
Such a system has a loop crossover frequency at very
low frequencies, typically below 10kHz. Slow transient
response designs require excessive output capacitance
to meet transient regulation requirements, increasing the
overall supply cost and size. An optimum loop compensation design is stable and quiet, but is not overcompensated, so it also has a fast response to minimize output
capacitance. There are numerous articles that discuss how
to optimize loop compensation networks for both voltage
mode-controlled and current mode-controlled SMPS [2-4].
Small signal modeling and loop compensation design can
be difficult for inexperienced power supply designers.
Linear Technology’s LTpowerCAD™ design tool handles
the complicated equations and makes loop compensation a much simpler task [6]. The LTspice® simulation
tool integrates all of Linear Technology’s part models and
provides additional time domain simulations to optimize
the design. However, bench test/verification of loop stability and transient performance is usually necessary in the
prototype stage.
In general, the performance of the closed voltage regulation
loop is evaluated by two important values: the loop bandwidth and the loop stability margin. The loop bandwidth
is quantified by the crossover frequency fC, at which the
loop gain T(s) equals one (0dB). The loop stability margin
is typically quantified by the phase margin or gain margin.
The loop phase margin Φm is defined as the difference
between the overall T(s) phase delay and –180° at the
crossover frequency. The gain margin is defined by the
difference between T(s) gain and 0dB at the frequency
where overall T(s) phase equals –180°. For a buck converter, typically 45 degree phase margin and 10dB gain
margin is considered sufficient. Figure 16 shows a typical
Bode plot of loop gain for a current mode LTC3829 12VIN
to 1VO/60A 3-phase buck converter. In this example, the
crossover frequency is 45kHz and the phase margin is 64
degrees. The gain margin is close to 20dB.
Figure 16. LTpowerCAD Design Tool Provides an Easy Way to Optimize the Loop Compensation and Load Transient
Response (3-Phase, Single-Output LTC3829 Buck Converter Example).
an140fa
AN140-13
Application Note 140
PolyPhase Buck Converter for High Current
Applications
Other Requirements of a High Performance Controller
As data processing systems become faster and larger,
their processor and memory units demand more current
at ever decreasing voltages. At these high currents, the
demands on power supplies are multiplied. In recent years,
PolyPhase (multiphase) synchronous buck converters
have been widely used for high current, low voltage power
supply solutions, due to their high efficiency and even
thermal distribution. Besides, with interleaved multiple
buck converter phases, the ripple current on both input
and output sides can be significantly reduced, resulting
in reduction of input and output capacitors and related
board space and cost.
In PolyPhase buck converters, precise current sensing and
sharing become extremely important. Good current sharing
ensures even thermal distribution and high system reliability. Because of their inherent current sharing capability in
steady state and during transients, current mode-controlled
bucks are usually preferred. Linear Technology’s LTC3856
and LTC3829 are typical PolyPhase buck controllers with
precise current sensing and sharing. Multiple controllers
can be connected in a daisy chain fashion for 2-, 3-, 4-,
6- and 12-phase systems with output current from 20A
to over 200A.
100k
680pF
5k
0.1µF
TG1
0.6µH
SENSE1+
SENSE1–
LTC3829
VFB
DIFFN
DIFFP
0.6µH
VOUT
1.2V
50A
0.002Ω
BG2
SENSE2+
SENSE2–
TG3
SW3
20k
VIN
SW2
DIFFOUT
VIN
6V TO 28V
BG1
FREQ
ITH
TK/SS
0.002Ω
22µF
35V
×3
PGND
TG2
SGND
20k
Component selection and schematic design is only half
of the supply design process. Proper PCB layout of a
switching supply design is always critical. In fact, its
importance can not be overstated. Good layout design
optimizes supply efficiency, alleviates thermal stress, and
most importantly, minimizes noise and interactions among
traces and components. To achieve this, it is important
for the designer to understand the current conduction
SW1
BOOST1
BOOST2
BOOST3
SW3 SW2 SW1
PCB Layout
+
VIN
INTVCC
4.7µF
Many other important features are required of a high
performance buck controller. Soft-start is usually needed
to control the inrush current during start-up. Overcurrent
limit and short-circuit latchoff can protect the supply when
the output is overloaded or shorted. Overvoltage protection safeguards the expensive load devices in the system.
To minimize system EMI noise, sometimes the controller
must be synchronized to an external clock signal. For low
voltage, high current applications, remote differential voltage sensing compensates for the PCB resistance voltage
drop and accurately regulates output voltage at the remote
load. In a complicated system with many output voltage
rails, sequencing and tracking among different voltage
rails is also necessary.
VIN
0.6µH
0.002Ω
BG3
SENSE3+
SENSE3–
+
COUT
470µF
4V
×4
AN140 F17
Figure 17. A 3-Phase, Single VO High Current Buck Converter Using the LTC3829
an140fa
AN140-14
Application Note 140
At the integration level, system engineers can decide
whether to choose a discrete, monolithic or fully integrated
power module solution. Figure 18 shows examples of discrete and power module solutions for typical point-of-load
supply applications. The discrete solution uses a controller
IC, external MOSFETs and passive components to build
the power supply on the system board. A major reason
to choose a discrete solution is low component bill of
materials (BOM) cost. However, this requires good power
supply design skills and relatively long development time.
A monolithic solution uses an IC with integrated power
MOSFETs to further reduce the solution size and component
count. It requires similar design skills and time. A fully
integrated power module solution can significantly reduce
design effort, development time, solution size and design
risk, but usually with a higher component BOM cost.
This application note uses buck converters as a simple example to demonstrate the design considerations of SMPS.
However, there are at least five other basic nonisolated
converter topologies (boost, buck/boost, Cuk, SEPIC and
Zeta converters) and at least five basic isolated converter
topologies (flyback, forward, push-pull, half-bridge and
full-bridge) which are not covered in this application note.
Each topology has unique properties that make it suited
for specific applications. Figure 19 shows simplified
schematics for the other nonisolated SMPS topologies.
There are other nonisolated SMPS topologies which
are combinations of the basic topologies. For example,
L
BOOST CONVERTER
+
+
+
–
LOAD
Selection of Various Solutions – Discrete, Monolithic
and Integrated Supplies
Other Basic Nonisolated DC/DC SMPS Topologies
CO
VOUT
–
VIN
DUTY
BUCK/BOOST CONVERTER
–
L
+
+
–
VIN
CO
LOAD
paths and signal flows in the switching power supply. It
usually requires significant effort to gain the necessary
experience. See Linear Technology Application Note 136
for detailed discussions. [7]
VOUT
+
DUTY
VIN
–
LOAD
+
–
CUK CONVERTER
CB
L2
+
L1
CO
VOUT
+
+
DUTY
+
VIN
(a)
L2
+
LOAD
+
–
SEPIC CONVERTER
CB
+
L1
CO
VOUT
–
DUTY
+
•
ZETA CONVERTER
CB
+
–
(b)
Figure 18. Examples of (a) a Discrete 12VIN to 3.3V/10A LTC3778
Supply; (b) a Fully Integrated 16VIN, Dual 13A or Single 26A
LTM4620 µModule® Step-Down Regulator
VIN
DUTY
+
LOAD
+
•
CO
VOUT
–
AN140 F19
Figure 19. Other Basic Nonisolated DC/DC Converter Topologies
an140fa
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
AN140-15
Application Note 140
Figure 20 shows a high efficiency, 4-switch synchronous
buck/boost converter based on the LTC3789 current mode
controller. It can operate with input voltages below, equal,
or above the output voltage. For example, the input can be
in the range of 5V to 36V, and the output can be a regulated
12V. This topology is a combination of a synchronous buck
converter and a synchronous boost converter, sharing a
single inductor. When VIN > VOUT, switches A and B operate
as an active synchronous buck converter, while the switch
C is always off and switch D is always on. When VIN <
VOUT, switches C and D operate as an active synchronous
boost converter, while switch A is always on and switch B
is always off. When VIN is close to VOUT, all four switches
operate actively. As a result, this converter can be very
efficient, with up to 98% efficiency for a typical 12V output
application. [12] The LT8705 controller further extends the
input voltage range up to 80V. To simplify the design and
increase power density, the LTM4605/4607/4609 further
integrate a complicated buck/boost converter into a high
density, easy-to-use power module. [13] They can be easily
paralleled with load sharing for high power applications.
4-SWITCH BUCK-BOOST
TOPOLOGY YIELDS HIGH
EFFICIENCY AT HIGH POWER
A
VIN
CIN
ONLY ONE INDUCTOR SIMPLIFIES
LAYOUT AND SAVES SPACE
SW2
L
SW1
B
D
VOUT
COUT
C
SNS+
SINGLE SENSE RESISTOR
KEEPS EFFICIENCY HIGH
LTC3789
R1
SNS+
SNS–
R2
AN140 F20
Figure 20. High Efficiency 4-Switch Buck-Boost Converter Operates
with Input Voltage Below, Equal or Above the Output Voltage
SUMMARY
In summary, linear regulators are simple and easy to use.
Since their series regulation transistors are operated in a
linear mode, supply efficiency is usually low when output
voltage is much lower than input voltage. In general, linear regulators (or LDOs) have low voltage ripple and fast
transient response. On the other hand, SMPS operate the
transistor as a switch, and therefore are usually much more
efficient than linear regulators. However, the design and
optimization of SMPS are more challenging and require
more background and experience. Each solution has its
own advantages and drawbacks for specific applications.
AN140-16
[1] V. Vorperian, “Simplified Analysis of PWM Converters
Using the Model of the PWM Switch: Parts I and II,” IEEE
Transactions on Aerospace and Electronic Systems, Mar.
1990, Vol. 26, No.2.
[2] R.B. Ridley, B.H.Cho, F.C.Lee, “Analysis and Interpretation of Loop Gains of Multi-Loop-Controlled Switching
Regulators,” IEEE Transactions on Power Electronics,
pp.489-498, Oct. 1988.
[3] J. Seago, “Opti-Loop Architecture Reduces Output Capacitance and Improves Transient Response,” Application
Note 76, Linear Technology Corp., May 1999.
[4] H. Dean Venable, “Optimum Feedback Amplifier Design
for Control Systems,” Venable Technical Paper.
[5] Linear Technology Data Sheets at www.linear.com.
[6] LTpowerCAD™ design tool at
www.linear.com/designtools/software.
[7] H. Zhang, “PCB Layout Considerations for Non-Isolated
Switching Power Supplies,” Application Note 136, Linear
Technology Corp., 2012.
[8] R. Dobbkin, “Low Dropout Regulator Can be Directly
Paralleled to Spread the Heat,” LT Journal of Analog Innovation, Oct. 2007.
[9] T. Phillips, “Produce High DC/DC Step-Down Ratios
in Tight Spaces with 30ns Minimum On-Time Controller
in 3mm × 3mm QFN,” LT Journal, Dec. 2009.
RSENSE
SNS–
REFERENCES
Linear Technology Corporation
[10] M. Subramanian, T. Nguyen and T. Phillips, “SubMilliohm DCR Current Sensing with Accurate Multiphase
Current Sharing for High Current Power Supplies,” LT
Journal, Jan. 2013.
[11] B. Abesingha, “Fast, Accurate Step-Down DC/DC
Controller Converts 24V Directly to 1.8V at 2MHz,” LT
Journal, Oct. 2011.
[12] T. Bjorklund, “High Efficiency 4-Switch Buck-Boost
Controller Provides Accurate Output Current Limit,” Linear
Technology Design Note 499.
[13] J. Sun, S. Young and H. Zhang, “µModule Regulator
Fits a (Nearly) Complete Buck-Boost Solution in 15mm
× 15mm × 2.8mm for 4.5V-36Vin to 0.8V-34V Vout,” LT
Journal, Mar. 2009.
an140fa
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